Ultrahigh Error Threshold for Surface Codes with Biased Noise
Author(s)
Tuckett, David K.; Bartlett, Stephen D.; Flammia, Steven Thomas
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We show that a simple modification of the surface code can exhibit an enormous gain in the error correction threshold for a noise model in which Pauli Z errors occur more frequently than X or Y errors. Such biased noise, where dephasing dominates, is ubiquitous in many quantum architectures. In the limit of pure dephasing noise we find a threshold of 43.7(1)% using a tensor network decoder proposed by Bravyi, Suchara, and Vargo. The threshold remains surprisingly large in the regime of realistic noise bias ratios, for example 28.2(2)% at a bias of 10. The performance is, in fact, at or near the hashing bound for all values of the bias. The modified surface code still uses only weight-4 stabilizers on a square lattice, but merely requires measuring products of Y instead of Z around the faces, as this doubles the number of useful syndrome bits associated with the dominant Z errors. Our results demonstrate that large efficiency gains can be found by appropriately tailoring codes and decoders to realistic noise models, even under the locality constraints of topological codes.
Date issued
2018-01Department
Massachusetts Institute of Technology. Laboratory for Nuclear ScienceJournal
Physical Review Letters
Publisher
American Physical Society
Citation
Tuckett, David K., et al. “Ultrahigh Error Threshold for Surface Codes with Biased Noise.” Physical Review Letters, vol. 120, no. 5, Jan. 2018. © 2018 American Physical Society
Version: Final published version
ISSN
0031-9007
1079-7114